Molecular characterization of a second abortive phage resistance gene present in Lactococcus lactis subsp. lactis ME2.

The fifth phage resistance factor from the prototype phage-insensitive strain Lactococcus lactis subsp. lactis ME2 has been characterized and sequenced. The genetic determinant for Prf (phage resistance five) was subcloned from the conjugative plasmid pTN20, which also encodes a restriction and modification system. Typical of other abortive resistance mechanisms, Prf reduces the efficiency of plaquing to 10(-2) to 10(-3) and decreases the plaque size and burst size of the small isometric-headed phage p2 in L. lactis subsp. lactis LM0230. However, normal-size plaques occurred at a frequency of 10(-4) and contained mutant phages that were resistant to Prf, even after repeated propagation through a sensitive host. Prf does not prevent phage adsorption or promote restriction and modification activities, but 90% of Prf+ cells infected with phage p2 die. Thus, phage infections in Prf+ cells are aborted. Prf is effective in both L. lactis subsp. lactis and L. lactis subsp. cremoris strains against several small isometric-headed phages but not against prolate-headed phages. The Prf determinant was localized by Tn5 mutagenesis and subcloning. DNA sequencing identified a 1,056-nucleotide structural gene designated abiC. Prf+ expression was obtained when abiC was subcloned into the lactococcal expression vector pMG36e. abiC is distinct from two other lactococcal abortive phage resistance genes, abiA (Hsp+, from L. lactis subsp. lactis ME2) and abi416 (Abi+, from L. lactis subsp. lactis IL416). Unlike abiA, the action of abiC does not appear to affect DNA replication. Thus, abiC represents a second abortive system found in ME2 that acts at a different point of the phage lytic cycle.     

Genetic analysis of chromosomal regions of Lactococcus lactis acquired by recombinant lytic phages

Recombinant phages are generated when Lactococcus lactis subsp. lactis harboring plasmids encoding the abortive type (Abi) of phage resistance mechanisms is infected with small isometric phages belonging to the P335 species. These phage variants are likely to be an important source of virulent new phages that appear in dairy fermentations. They are distinguished from their progenitors by resistance to Abi defenses and by altered genome organization, including regions of L. lactis chromosomal DNA. The objective of this study was to characterize four recombinant variants that arose from infection of L. lactis NCK203 (Abi(+)) with phage phi31. HindIII restriction maps of the variants (phi31.1, phi31.2, phi31.7, and phi31.8) were generated, and these maps revealed the regions containing recombinant DNA. The recombinant region of phage phi31.1, the variant that occurred most frequently, was sequenced and revealed 7.8 kb of new DNA compared with the parent phage, phi31. This region contained numerous instances of homology with various lactococcal temperate phages, as well as homologues of the lambda recombination protein BET and Escherichia coli Holliday junction resolvase Rus, factors which may contribute to efficient recombination processes. A sequence analysis and phenotypic tests revealed a new origin of replication in the phi31.1 DNA, which replaced the phi31 origin. Three separate HindIII fragments, accounting for most of the recombinant region of phi31.1, were separately cloned into gram-positive suicide vector pTRK333 and transformed into NCK203. Chromosomal insertions of each plasmid prevented the appearance of different combinations of recombinant phages. The chromosomal insertions did not affect an inducible prophage present in NCK203. Our results demonstrated that recombinant phages can acquire DNA cassettes from different regions of the chromosome in order to overcome Abi defenses. Disruption of these regions by insertion can alter the types and diversity of new phages that appear during phage-host interactions.     

Lactococcus lactis lytic bacteriophages of the P335 group are inhibited by overexpression of a truncated CI repressor

Phages of the P335 group have recently emerged as important taxa among lactococcal phages that disrupt dairy fermentations. DNA sequencing has revealed extensive homologies between the lytic and temperate phages of this group. The P335 lytic phage phi31 encodes a genetic switch region of cI and cro homologs but lacks the phage attachment site and integrase necessary to establish lysogeny. When the putative cI repressor gene of phage phi31 was subcloned into the medium-copy-number vector pAK80, no superinfection immunity was conferred to the host, Lactococcus lactis subsp. lactis NCK203, indicating that the wild-type CI repressor was dysfunctional. Attempts to clone the full-length cI gene in Lactococcus in the high-copy-number shuttle vector pTRKH2 were unsuccessful. The single clone that was recovered harbored an ochre mutation in the cI gene after the first 128 amino acids of the predicted 180-amino-acid protein. In the presence of the truncated CI construct, pTRKH2::CI-per1, phage phi31 was inhibited to an efficiency of plaquing (EOP) of 10(-6) in NCK203. A pTRKH2 subclone which lacked the DNA downstream of the ochre mutation, pTRKH2::CI-per2, confirmed the phenotype and further reduced the phi31 EOP to <10(-7). Phage phi31 mutants, partially resistant to CI-per, were isolated and showed changes in two of three putative operator sites for CI and Cro binding. Both the wild-type and truncated CI proteins bound the two wild-type operators in gel mobility shift experiments, but the mutated operators were not bound by the truncated CI. Twelve of 16 lytic P335 group phages failed to form plaques on L. lactis harboring pTRKH2::CI-per2, while 4 phages formed plaques at normal efficiencies. Comparisons of amino acid and DNA level homologies with other lactococcal temperate phage repressors suggest that evolutionary events may have led to inactivation of the phi31 CI repressor. This study demonstrated that a number of different P335 phages, lytic for L. lactis NCK203, have a common operator region which can be targeted by a truncated derivative of a dysfunctional CI repressor.     

Identification of four phage resistance plasmids from Lactococcus lactis subsp. cremoris HO2

The bacteriophage-host sensitivity patterns of 16 strains of Lactococcus lactis originally isolated from a mixed strain Cheddar cheese starter culture were determined. Using phages obtained from cheese factory whey, four of the strains were found to be highly phage resistant. One of these isolates, Lactococcus lactis subsp. cremoris HO2, was studied in detail to determine the mechanisms responsible for the phage insensitivity phenotypes. Conjugal transfer of plasmid DNA from strain HO2 allowed a function to be assigned to four of its six plasmids. A 46-kb molecule, designated pCI646, was found to harbor the lactose utilization genes, while this and plasmids of 58 kb (pCI658), 42 kb (pCI642), and 4.5 kb (pCI605) were shown to be responsible for the phage resistance phenotypes observed against the small isometric-headed phage phi712 (936 phage species) and the prolate-headed phage phic2 (c2 species). pCI658 was found to mediate an adsorption-blocking mechanism and was also responsible for the fluffy pellet phenotype of cells containing the molecule. pCI642 and pCI605 were both shown to be required for the operation of a restriction-modification system.     

Identification of Lactococcus lactis genes required for bacteriophage adsorption

The aim of this work was to identify genes in Lactococcus lactis subsp. lactis IL1403 and Lactococcus lactis subsp. cremoris Wg2 important for adsorption of the 936-species phages bIL170 and phi 645, respectively. Random insertional mutagenesis of the two L. lactis strains was carried out with the vector pGh9:ISS1, and integrants that were resistant to phage infection and showed reduced phage adsorption were selected. In L. lactis IL1403 integration was obtained in the ycaG and rgpE genes, whereas in L. lactis Wg2 integration was obtained in two genes homologous to ycbC and ycbB of L. lactis IL1403. rgpE and ycbB encode putative glycosyltransferases, whereas ycaG and ycbC encode putative membrane-spanning proteins with unknown functions. Interestingly, ycaG, rgpE, ycbC, and ycbB are all part of the same operon in L. lactis IL1403. This operon is probably involved in biosynthesis and transport of cell wall polysaccharides (WPS). Binding and infection studies showed that phi645 binds to and infects L. lactis Wg2, L. lactis IL1403, and L. lactis IL1403 strains with pGh9:ISS1 integration in ycaG and rgpE, whereas bIL170 binds to and infects only L. lactis IL1403 and cannot infect Wg2. These results indicate that phi 645 binds to a WPS structure present in both L. lactis IL1403 and L. lactis Wg2, whereas bIL170 binds to another WPS structure not present in L. lactis Wg2. Binding of bIL170 and phi 645 to different WPS structures was supported by alignment of the receptor-binding proteins of bIL170 and phi 645 that showed no homology in the C-terminal part.     

Effect of exopolysaccharides on phage-host interactions in Lactococcus lactis

In this study, we report that Lactococcus lactis strains producing exopolysaccharides (EPS) are sensitive to virulent phages. Eight distinct lytic phages (Q61 to Q68) specifically infecting Eps(+) strains were isolated in 47 buttermilk samples obtained from 13 North American factories. The eight phages were classified within the 936 species by the multiplex PCR method, indicating that these phages are not fundamentally distinct from those infecting Eps(-) L. lactis strains. The host range of these phages was determined with 19 Lactococcus strains, including 7 Eps(+) and 12 Eps(-) cultures. Three phages (Q62, Q63, and Q64) attacked only the Eps(+) strain SMQ-419, whereas the five other phages (Q61, Q65, Q66, Q67, and Q68) infected only the Eps(+) strain SMQ-420. The five other Eps(+) strains (H414, MLT2, MLT3, SMQ-461, and SMQ-575) as well as the 12 Eps(-) strains were insensitive to these phages. The monosaccharide composition of the polymer produced by the seven Eps(+) strains was determined. The EPS produced by strains MLT3, SMQ-419, and SMQ-575 contained glucose, galactose, and rhamnose. The EPS fabricated by H414 contained only galactose. The EPS made by MLT2, SMQ-420, and SMQ-461 contained glucose and galactose. These findings indicate that the sugar composition of the EPS has no effect on phage sensitivity. The plasmid encoding the eps operon was cured from the two phage-sensitive strains. The cured derivatives were still phage sensitive, which indicates that EPS are not necessary for phage infection. Phage adsorption assays showed that the production of EPS does not confer a significant phage resistance phenotype.     

A triggered-suicide system designed as a defense against bacteriophages.

A novel bacteriophage protection system for Lactococcus lactis based on a genetic trap, in which a strictly phage-inducible promoter isolated from the lytic phage phi31 is used to activate a bacterial suicide system after infection, was developed. The lethal gene of the suicide system consists of the three-gene restriction cassette LlaIR+, which is lethal across a wide range of gram-positive bacteria. The phage-inducible trigger promoter (phi31P) and the LlaIR+ restriction cassette were cloned in Escherichia coli on a high-copy-number replicon to generate pTRK414H. Restriction activity was not apparent in E. coli or L. lactis prior to phage infection. In phage challenges of L. lactis(pTRK414H) with phi31, the efficiency of plaquing was lowered to 10(-4) and accompanied by a fourfold reduction in burst size. Center-of-infection assays revealed that only 15% of infected cells released progeny phage. In addition to phage phi31, the phi31P/LlaIR+ suicide cassette also inhibited four phi31-derived recombinant phages at levels at least 10-fold greater than that of phi31. The phi31P/LlaIR+-based suicide system is a genetically engineered form of abortive infection that traps and eliminates phages potentially evolving in fermentation environments by destroying the phage genome and killing the propagation host. This type of phage-triggered suicide system could be designed for any bacterium-phage combination, given a universal lethal gene and an inducible promoter which is triggered by the infecting bacteriophage.     

Phenotypic Consequences of Altering the Copy Number of abiA, a Gene Responsible for Aborting Bacteriophage Infections in Lactococcus lactis

The abiA gene (formerly hsp) encodes an abortive phage infection mechanism which inhibits phage DNA replication. To analyze the effects of varying the abiA gene dosage on bacteriophage resistance in Lactococcus lactis, various genetic constructions were made. An IS946-based integration vector, pTRK75, was used to integrate a single copy of abiA into the chromosomes of two lactococcal strains, MG1363 and NCK203. In both strains, a single copy of abiA did not confer any significant phage resistance on the host except for one of the MG1363 integrants, NCK625, which exhibited a slightly higher level of resistance to phages sk1 and p2. Hybridization of the total cellular RNA from NCK625 to an abiA-specific probe indicated that the integration took place downstream of a promoter causing stronger expression of abiA in this integrant. Three abiA-containing plasmids of various copy numbers were introduced into both strains, and the recombinants were evaluated for resistance to phages c2, p2, sk1, and phi31. Plasmid pTRK18 has a copy number of approximately six (cn = 6) and caused a decreased plaque size for all phages evaluated. Integration of pTRK75 into a native plasmid of NCK203 generated pTRK362 (cn = 13), which caused a reduced efficiency of plaquing (EOP = 10) and reduced plaque size. A high-copy-number abiA plasmid (pTRK363), based on the pAMbeta1 origin of replication, was also constructed (cn = 100). Plasmid pTRK363 caused a significant reduction in EOP (10 to 10) and plaque size for all phages tested, although in some cases, this plasmid caused the evolution of AbiA-resistant phage derivatives. Altering the gene dosage or expression level of abiA significantly affects the phage resistance levels.     

Cloning and DNA sequence analysis of two abortive infection phage resistance determinants from the lactococcal plasmid pNP40.

The lactococcal plasmid pNP40, from Lactococcus lactis subsp. lactis biovar diacetylactis DRC3, confers complete resistance to the prolate-headed phage phi c2 and the small isometric-headed phage phi 712 in L. lactis subsp. lactis MG1614. A 6.0-kb NcoI fragment of pNP40 cloned in the lactococcal Escherichia coli shuttle vector pAM401 was found to confer partial resistance to phi 712. Subcloning and deletion analysis of the recombinant plasmid pPG01 defined a 2.5-kb ScaIHpaI fragment as conferring phage insensitivity. Sequence analysis of this region confirmed the presence of two overlapping open reading frames (ORFs). Further subcloning of pNP40 to characterize the resistance determinant active against phi c2 identified a 5.6-kb EcoRV fragment of pNP40 which, when cloned in pAM401, conferred partial resistance to both phi c2 and phi 712. Subcloning and deletion analysis of the recombinant plasmid pCG1 defined a 3.7-kb EcoRV-XbaI fragment as encoding phage insensitivity. DNA sequence analysis of this region revealed the presence of a single complete ORF. The introduction of a frameshift mutation at the unique BglII site within this ORF disrupted the phage resistance phenotype, confirming that this ORF is responsible for the observed phage insensitivity. The mechanisms encoded by pPG01 and pCG1 in L. lactis subsp. lactis MG1614 conformed to the criteria defining abortive infection and were designated AbiE and AbiF, respectively. Analysis of the phage DNA content of phi 712-infected hosts containing AbiF demonstrated that it inhibited the rate of phage DNA replication, while AbiE had little effect on phage DNA replication, suggesting a later target of inhibition. The predicted protein product of abiF shows significant homology to the products of two other lactococcal abortive infection genes, abiD and abiD1.     

Phenotypic and genetic characterization of the bacteriophage abortive infection mechanism AbiK from Lactococcus lactis.

The natural plasmid pSRQ800 isolated from Lactococcus lactis subsp. lactis W1 conferred strong phage resistance against small isometric phages of the 936 and P335 species when introduced into phage-sensitive L. lactis strains. It had very limited effect on prolate phages of the c2 species. The phage resistance mechanism encoded on pSRQ800 is a temperature-sensitive abortive infection system (Abi). Plasmid pSRQ800 was mapped, and the Abi genetic determinant was localized on a 4.5-kb EcoRI fragment. Cloning and sequencing of the 4.5-kb fragment allowed the identification of two large open reading frames. Deletion mutants showed that only orf1 was needed to produce the Abi phenotype. orf1 (renamed abiK) coded for a predicted protein of 599 amino acids (AbiK) with an estimated molecular size of 71.4 kDa and a pI of 7.98. DNA and protein sequence alignment programs found no significant homology with databases. However, a database query based on amino acid composition suggested that AbiK might be in the same protein family as AbiA. No phage DNA replication nor phage structural protein production was detected in infected AbiK+ L. lactis cells. This system is believed to act at or prior to phage DNA replication. WHen cloned into a high-copy vector, AbiK efficiency increased 100-fold. AbiK provides another powerful tool that can be useful in controlling phages during lactococcal fermentations.     

Identification of the receptor-binding protein in 936-species lactococcal bacteriophages

The aim of this work was to identify genes responsible for host recognition in the lactococcal phages sk1 and bIL170 belonging to species 936. These phages have a high level of DNA identity but different host ranges. Bioinformatic analysis indicated that homologous genes, orf18 in sk1 and orf20 in bIL170, could be the receptor-binding protein (RBP) genes, since the resulting proteins were unrelated in the C-terminal part and showed homology to different groups of proteins hypothetically involved in host recognition. Consequently, chimeric bIL170 phages carrying orf18 from sk1 were generated. The recombinant phages were able to form plaques on the sk1 host Lactococcus lactis MG1614, and recombination was verified by PCR analysis directly with the plaques. A polyclonal antiserum raised against the C-terminal part of phage sk1 ORF18 was used in immunogold electron microscopy to demonstrate that ORF18 is located at the tip of the tail. Sequence analysis of corresponding proteins from other lactococcal phages belonging to species 936 showed that the N-terminal parts of the RBPs were very similar, while the C-terminal parts varied, suggesting that the C-terminal part plays a role in receptor binding. The phages investigated could be grouped into sk1-like phages (p2, fd13, jj50, and phi 7) and bIL170-like phages (P008, P113G, P272, and bIL66) on the basis of the homology of their RBPs to the C-terminal part of ORF18 in sk1 and ORF20 in bIL170, respectively. Interestingly, sk1-like phages bind to and infect a defined group of L. lactis subsp. cremoris strains, while bIL170-like phages bind to and infect a defined group of L. lactis subsp. lactis strains.     

Bacteriophages of lactobacilli

Lactobacilli are members of the bacterial flora of lactic starter cultures used to generate lactic acid fermentation in a number of animal or plant products used as human or animals foods. They can be affected by phage outbreaks, which can result in faulty and depreciated products. Two groups of phages specific of Lactobacillus casei have been thoroughly studied. 1. The first group is represented by phage PL-1. This phage behaves as lytic in its usual host L. casei ATCC 27092, but can lysogenize another strain, L. casei ATCC 334. Bacterial receptors of this phage are located in a cell-wall polysaccharide and rhamnose is the main component of the receptors. Ca2+ and adenosine triphosphate (ATP) are indispensable to ensure the injection of the phage DNA into the bacterial cell. The phage DNA is double-stranded, mostly linear, but with cohesive ends which enables it to be circularized. The vegetative growth of PL-1 proceeds according to the classical mode. Cell lysis is produced by an N-acetyl-muramidase at the end of vegetative growth. 2. The second group is represented by the temperate phage phi FSW of L. casei ATCC27139. It has been shown how virulent phages originate from this temperate phage in Japanese dairy plants. The lysogenic state of phi FSW can be altered either by point mutations or by the insertion of a mobile genetic element called ISL 1, which comes from the bacterial chromosome. This is the first transposable element that has been described in lactobacilli. Lysogeny appears to be widespread among lactobacilli since one study showed that 27% of 148 strains studied, representing 15 species, produced phage particles after induction by mitomycin C. Similarly, 23 out of 30 strains of Lactobacillus salivarius are lysogenic and produce, after induction by mitomycin C, temperate phages, killer particles, or defective phages. Temperate phages have also been found in 10 out of 105 strains of Lactobacillus bulgaricus or Lactobacillus lactis after induction by mitomycin C. Phages so far studied of the latter 2 and closely related lactobacilli, either temperate or isolated as lytic, may be divided into 4 unrelated groups called a, b, c and d. Most of these phages are found in group a and an unquestionable relationship has already been shown between lytic phages and temperate phages that belong to this group. Lytic phage LL-H of L. lactis LL 23, isolated in Finland, is one of the most representative of those of group a and has been extensively studied on the molecular level.     

Characterization and genomic analysis of phage asccphi28, a phage of the family Podoviridae infecting Lactococcus lactis

Bacteriophage asccphi28 infects dairy fermentation strains of Lactococcus lactis. This report describes characterization of asccphi28 and its full genome sequence. Phage asccphi28 has a prolate head, whiskers, and a short tail (C2 morphotype). This morphology and DNA hybridization to L. lactis phage P369 DNA showed that asccphi28 belongs to the P034 phage species, a group rarely encountered in the dairy industry. The burst size of asccphi28 was found to be 121 +/- 18 PFU per infected bacterial cell after a latent period of 44 min. The linear genome (18,762 bp) contains 28 possible open reading frames (ORFs) comprising 90% of the total genome. The ORFs are arranged bidirectionally in recognizable functional modules. The genome contains 577 bp inverted terminal repeats (ITRs) and putatively eight promoters and four terminators. The presence of ITRs, a phage-encoded DNA polymerase, and a terminal protein that binds to the DNA, along with BLAST and morphology data, show that asccphi28 more closely resembles streptococcal phage Cp-1 and the phi29-like phages that infect Bacillus subtilis than it resembles common lactococcal phages. The sequence of this phage is the first published sequence of a P034 species phage genome.     

Analysis of Lactobacillus phages and bacteriocins in American dairy products and characterization of a phage isolated from yogurt.

Yogurt and acidophilus milk that contain Lactobacillus acidophilus could promote human health because L. acidophilus can inhibit enteric and food-borne microbial pathogens. To evaluate the stability of diary L. acidophilus cultures, we studied whether some diary lactobacilli could be inhibited by phages or bacteriocins released by other dairy lactobacilli. From 20 yogurts and two acidophilus milks purchased at local food markets, 38 Lactobacillus strains were isolated. Eight Lactobacillus type strains were used as controls. With mitomycin induction and agar spot assay, phages and bacteriocins were isolated from these strains and their activities were analyzed. Lactobacillus strains from 11 yogurts released phages, while the strains from most of the remaining products released bacteriocins. One phage, designated phi y8, was characterized. It was spontaneously released from its host strain L. acidophilus Y8, at a rate of about 10(4)/ml. This phage lysed nine other dairy Lactobacillus strains tested. It had a burst size of 100, an elongated prolate head of 39 by 130 nm, a long, flexible but noncontractile tail of 300 nm, and a 54.3-kb linear double-stranded DNA. DNA fingerprinting analysis indicated that L. acidophilus phages of nine yogurts in this study belonged to the same type as phi y8. Although they may be sensitive to bacteriocins, all lysogens resisted further phage attacks, whereas most nonlysogens were sensitive to both phages and bacteriocins. Therefore, Lacotbacillus cultures of some American yogurts and acidophilus milks may be unstable or unsafe because they can either be inhibited by phages or bacteriocins or release them to inhibit lactobacilli or other diary products.     

Isolation and propagation of phages naturally associated with the aizawai variety of Bacillus thuringiensis

This study describes the isolation of a phage, using mitomycin C and u.v. light, from each of four strains (HD67, HD130, HD228 and HD248) of Bacillus thuringiensis H-serotype 7 (var. aizawai). It also describes the isolation of two indicator strains (12.13 and HD102) for these phages (phi HD67, phi HD130, phi HD228 and phi HD248) and the ideal conditions, using these indicator strains, for maximum phage production.     

Potential of AbiS as defence mechanism determined by conductivity measurement

AIM: To compare pH and conductivity used in the determination of growth in reconstituted skim milk (RSM), to determine whether the presence of one or two plasmids in Lactococcus lactis had any influence on growth, and whether AbiS improved bacteriophages resistance of L. lactis. METHODS AND RESULTS: Conductivity and pH were used to determine growth in RSM. A small increase in the generation time was found with increasing number of plasmids, while their size was unimportant. The introduction of a plasmid-encoding AbiS did only enhance the level of phage resistance significant when other plasmids encoding either AbiS1 or the restriction modification system LlaBIII was present. CONCLUSIONS: The earliest detection of growth was observed by measuring pH, rather than conductance. The plasmid-encoded AbiS system has a potential to be used as a phage resistance mechanisms in L. lactis during milk fermentations, especially when combined with other anti-phage mechanisms. SIGNIFICANCE AND IMPACT OF THE STUDY: This study widened the knowledge about the influence of plasmid introduction on the growth rate of L. lactis, which is important for the construction of new strains. The level of protection against 936 groups of phages was only significant when the mechanism was present together with the RM system LlaBIII.     

Biodiversity of Lactococcus lactis bacteriophages in Polish dairy environment

We present here the results of an exploration of the bacteriophage content of dairy wheys collected from milk plants localized in various regions of Poland. Thirty-three whey samples from 17 regions were analyzed and found to contain phages active against L. lactis strains. High phage titer in all whey samples suggested phage-induced lysis to be the main cause of fermentation failures. In total, over 220 isolated phages were examined for their restriction patterns, genome sizes, genetic groups of DNA homology, and host ranges. Based on DNA digestions the identified phages were classified into 34 distinct DNA restriction groups. Phage genome sizes were estimated at 14-35 kb. Multiplex PCR analysis established that the studied phages belong to two out of the three main lactococcal phage types--c2 and 936, while P335-type phages were not detected. Yet, analyses of bacterial starter strains revealed that the majority of them are lysogenic and carry prophages of P335-type in their chromosome. Phage geographical distribution and host range are additionally discussed.     

Transformation in Staphylococcus aureus: role of bacteriophage and incidence of competence among strains.

When used in a helper phage capacity, phages 29, 52, 52A, 79, 80, 55, 71, 53, 83A, 85, 95, 96, phi11, and 80 alpha, all serological group B Staphylococcus phages, conferred competence for transformation to S. aureus 8325-4, a strain that does not normally become competent. Of the serological group A phages tested, only phage 3A showed significant competence-conferring activity. Phages 29, 55, 53, 83A, .85, 95, phi11, and 80 alpha showed an enhancement of competence-conferring activity if exposure to the cells occurred in the presence of nromal rabbit serum. All of the propagating strains for the Staphylococcus reference typing phages were rendered competent for transformation by exposure to at least one of these helper phages. The use of a helper phage to confer competence to S. aureus did not result in distortion of the genetic linkages observed in an inherently competent strain. Lysogenization by phages phi11 or 83A is shown not to be required for the expression of competence, and evidence is presented which indicates that competence in the inherently competent 8325 strain is due to a helper phage effect initiated by the adsorption to cells of phi11 virion parts [or phi11 particles in the case of the single lysogen 8325-4(phi11)] that have been liberated by prophage induction.     

Abortive phage resistance mechanism AbiZ speeds the lysis clock to cause premature lysis of phage-infected Lactococcus lactis

The conjugative plasmid pTR2030 has been used extensively to confer phage resistance in commercial Lactococcus starter cultures. The plasmid harbors a 16-kb region, flanked by insertion sequence (IS) elements, that encodes the restriction/modification system LlaI and carries an abortive infection gene, abiA. The AbiA system inhibits both prolate and small isometric phages by interfering with the early stages of phage DNA replication. However, abiA alone does not account for the full abortive activity reported for pTR2030. In this study, a 7.5-kb region positioned within the IS elements and downstream of abiA was sequenced to reveal seven additional open reading frames (ORFs). A single ORF, designated abiZ, was found to be responsible for a significant reduction in plaque size and an efficiency of plaquing (EOP) of 10(-6), without affecting phage adsorption. AbiZ causes phage phi31-infected Lactococcus lactis NCK203 to lyse 15 min early, reducing the burst size of phi31 100-fold. Thirteen of 14 phages of the P335 group were sensitive to AbiZ, through reduction in either plaque size, EOP, or both. The predicted AbiZ protein contains two predicted transmembrane helices but shows no significant DNA homologies. When the phage phi31 lysin and holin genes were cloned into the nisin-inducible shuttle vector pMSP3545, nisin induction of holin and lysin caused partial lysis of NCK203. In the presence of AbiZ, lysis occurred 30 min earlier. In holin-induced cells, membrane permeability as measured using propidium iodide was greater in the presence of AbiZ. These results suggest that AbiZ may interact cooperatively with holin to cause premature lysis.